Temperature control system



Sept. 23, w41. w. K. WALKER TEMPERATURE CONTROL YSYSTEM Filed April 19, 1938 2 Sheets-Sheet l ffl ylNvl-:N'roR VV||ha Wu er BY E Hl ATTORNEY ILLUSTRATI VE TEMPERATURES. OF

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ELEMENTS 0N RADIATOR Sept. 23, 19.41. K WALKER I 2,256,791?

TEMPERATURE CON'I-ROL 4SYSTEM Filed April 19, 1938 2 sheets-sheet 2 -INVENTOR M522@ HIS ORNEY Patented Sept. 23, 1941 William K. Walker, New York, N. Y., 'assignon .by Alle!! m l can Standard Sanitary Corporation, N. Y., a corporation o! Delaware mesne assignments,

application spi-ii is, 19st, sensi No. 26ans' (ci. sas-91)' 1o Claims.

My present invention relates to improved means and method of regulating heating systems.

A characteristic of the present invention resides in'the control of the lsupply o! thermal medium to eiect any desired temperature within a building' or other structure vequipped witha suitable thermal system, in correlation with variant outdoor, i. e., weather temperatures.

Pursuant to the invention, control of' the instants of starting and shutting oi o! the supply oi' the thermal medium is accomplished by anovel combination of a thermostat responsive to outdoor temperature and asserting control over the shutting off or supply of said thermal medium, means disposed ln. heat radiating relation with said thermostat and operative to supplement the outdoor temperature in attaining a predetermined operation temperature of said thermostat, and means associated with a radiator or other element of the building thermal system to control the amount of heat output o! said thermostat-associated heat radiating means.

Preferably, the thermostat-associated heat radiating means are electrical heating coils or equivalent units, the heat output of which is l controlled by altering the total resistance of the electrical circuit in which such heating elements are placed. Most preferably, such control o! the heat radiating relation dition being a common result of controlling the heating system by means o! an indoor thermostat 'independently' o1' outdoor temperature, is thus avoided.

, One preferred embodiment oi the invention therefore comprises a temperature-sensitive electrical make and break device contained ina suitable housing located on the exterior of a building, within which housing additionally are disposed one or more electric iheating elements in the temperaturesensitive elements of such thermostatic device. In the electrical'circuit` of the heating elements are placed one or more elements o! electrically conductive resistance material disposed in heatyexchange contact with the stated control element, such resistancaelements, when employed in plurality, being disposed along the path-'of ilow of heat medium through the stated radiator. It

reistance is eiected by including, as part' oi' such electrical circuit, electrical conducting materials in which the electrical resistance varies appreciably with temperature, and disposing such` materials in heat-exchange relationship to a selected radiator of the heating system, or other heat-exchange or heat-conducting means thereof. The heat supplyto such radiator or the like serves as the basis for the heat supply to other heat exchangersoi the system in maintaining the desired temperature condition withinlthe building or other enclosure served by such system. l

e It is thus s Afeature of 'the present invention that the supply of heat to a building or other enclosure is governed bya correlation of the outdoor temperature and the temperature ora controlling radiator.V

It is a second feature o! the present invention lished by the supply of heat medium to a selected controlling element, may be regulated by, and maintained in desired relationship to, the outdoor temperature, the supply oi' heat medium to the control radiator being lesser or greater as the outdoor temperature rises or falls. The condition known as cold '10 in the heating art. such conhas been found that by selecting a radiator or .equivalent heat exchanger as the control element,'a substantially straight line relationship between outdoor temperature and radiator temperature may be attained by disposing the greater portion of the total resistance value ot such elements at or near the point -oi entrance of the thermal mediumto the radiator. 'I'he temperature control system may be completed by provid- 'l ing suitable manually or automatically operable means for vvarying the total resistance of the circuit, and suitably establishing the outdoor thermostatic make and break device in an .electrical circuit serving an automatic heat-now valve, automatic combustion control, or the like which either instigates or controls the ow of thermal medium to and through the heating system. As

is' well understood, the outdoor thermostatic device may actas a make and break switch serving a suitable relay operative to perform the actual control operation ot such device.

Desirably, but not necessarily, a secondoutdoor temperature-responsive thermostatic device may t be employed, such device 'serving to control a that the supply of heat to a building, as estab- Pint.

heating element in the first-mentioned outdoor thermostat. By employing such auxiliary control thermostat, increase of accuracy oi control is obtained; additionally, such thermostat may serve as a limit -switch to positively shut od the automatic valve orthe like in the event that the outdoor temperature rises above a predetermined It will be understood-that under particular operating conditions, some part of the heating system other than a radiator may be selected as valve or automatic 1 the basis for control, such selection being in accordance with accepted heating principles, well understood by those skilled in the art.

Further features andv objects of the invention will be more fully understood from the following detail description and the accompanying drawings, in which:

Fig. 1 is a Ischematic and partly diagrammatic view indicating typical forms of the invention;

Fig. 2 is a diagram of the electrical circuit of a preferred arrangement typified in Fig. 1;

Fig. 3 is a diagram indicating illustrative, i. e., typical, temperatures ofthe control elements on a selected radiator, plotted as abscissae in relation tooutdoor temperatures plotted as ordinates, for each of three desired building temperature conditions;

Fig. 4 is a schematic view of a typical multiroom structure served by a heating system embodying the present invention, reference being directed to Figs. 1 and 2 for complete disclosure of the electrical circuit thereof; and Fig. 5 is a schematic wiring diagram showing a second arrangement of the outdoor thermostatic control devices.

In schematic' view, Fig. 1 indicates the locations, outdoor and indoor, of elements of typical embodiments of the invention, one preferred embodiment being shown in electrical diagram in Fig. 2.

In carrying out my invention, as for example, for the control of the heating of a `building or other structure comprising a relatively large number of rooms or other spaces served by radiators or equivalent heat exchange units of the heating system, any element of the heating system having a deiinite temperature relationship to other elements of the heating system may be selected as the indoor control point. The selection of such control point may be determined in accord with known principles of heating of multi-room buildings.

In the system indicated in Fig. 4,.a radiator I supplied, for example, with steam as the heating medium, as through the indicated iniiow piping I I, is employed as such control point. The

heating system may include return piping indi- I cated at I2; I2a represents a steam trap; I2b indicates a conventional shut-oit valve, located at the inflow side of the radiator.

The radiator III may be any suitable unit of the building heating system, deriving its steam or other thermal medium from a main or supply pipe IIa common to other heat-exchange units IDa of the building. As will be understood, the radiation or heat-exchange values of each radiator should be so established with respect to the heat loss characteristics of the room or enclosure served, that suilicient heat is supplied to such room to maintain desired indoor temperature at the same predetermined outdoor 'temperature condition used is proportioning the radiation in the other rooms. Further, each radiator should be so proportioned that capacity thereof affords sufficient heat emission for maintenance of such indoor temperature condition at the predetermined minimum outdoor temperature and weather condition.

The inlet valves of the radiators of the system may beprovided with suitably sized oriiices, calculated to compensate for the distance of travel of the steam and other factors known to those skilled in the art, to the end that adequate delivery of steam is assured to the most remote radiator. By the exercise of sound engineering practices, in conformity with the above, a partial filling of the control radiator iii may represent a corresponding percentage of ll of other radiators in the system, and therefore the average temperature of radiator I8 may be characteristic of other radiators served by the common supply main IIa.

In Fig. l, It represents a portion of an outer wall of a building equipped with the thermal system; I5 indicates the room or other space in which the selected, controlling radiator I0 is located', and I6 indicates the floor` line of such room or space I5. The control system includes a temperaturesensitive electrical make and break device I'I, housed within a suitable enclosure II on the outside of the building wall III. The selection of the proper location for thermostat I1 may accord with principles known to those skilled in the art. For example, if the heating system of the building is zoned, the thermostat should be suitably placed on the side of the building to which heat is supplied.

Thermostat I'I may be of any conventional type, such as bi-metallic, bellows, or pressure spring. Preferably, the thermostatic make and break thereof is snap-action, to prevent a condition of iiuttering contact. As a simple form of thermostat, I have shown' a temperaturesensitive bi-metallic element I8, electrically conducting, and an operatively associated xed contact I9. Itis understood that conventional adjustment means are provided to establish the temperature at which the element I8 moves into or out of electric circuit closing status. i

Thermostat I'I may control, as by the electrical leads 20, 2I, any suitable electrical Valve or other device 22 for controlling the flow of heat through main I Ia supplying the system of which the control radiator I0 is a component, or for controlling the actual generation of heat medium, as steam or hot water, by automatic combustion devices.

Such thermal medium control device 22 may be operated by employment of electrical energy furnished by any suitable electrical source, usually' through a relay operated circuit, as is well known to those skilled in the art.

Referring to Fig. 2, in which the electrical cir-- cuit of my improved control system is diagrammatically shown, the circuit includes one or more elements, as I3, I3a, I3b, I3c, made of an electrically conducting material of which the electrical resistance value varies with the temperature of such material. Preferably, such material is of a type which has a lessened resistance on increase in temperature; such material is commonly known as a negative resistance material. It will be understood that other types of temperature-affected resistance materials may be used, such as so-called positive materials, with appropriate changes in the electrical circuit.

The stated resistance elements are shown as being in series electrical connection; such manner of connection has been found preferable, but a multiple connection may be employed with suitable alteration. In applying the stated resistance elements to the radiator, they' should be electrically insulated therefrom but in advantageous heat-ow relation therewith. Bakelite or similar insulating mountings have been found satisfactory.

In series electricalconnection with elements I3, I3a, I3b, I3c, and disposed Within housing I'I so as to be in heat radiating relation to the sensitive element I8 of thermostat II, there is procated at 25; lead wire 23 connects coil -24 to one of the plurality of negative resistance elements, as I3c. The maior electrical circuit is completed by a connection 32 from element I3 to a rheostat or other resistance regulation device 33. The adjustable contact of such rheostat is connected, by a suitable conductorl 34, to the second wire of the power source.25, completing the'circuit.

Power source 25 may connect into the usual 110 volt building service. Ii alternating current serves the building, it -is preferable to employ a transformer, as indicated at 25a, to suitably reduce the building service voltage, as from 110to 30, for example, in the interests o f simplifying the wiring of the system.'

To afford a more accurate control, and to provide a means for positively shutting 6i! the heat at its source, at or-above a certain outdoor temperature, it has been found advantageous to use an auxiliary thermostat, as 25, mounted in a suitable housing adjacent to, but thermally insulated from, housing I1. Thermostat 25 may be of any suitable type, bi-metallic or bellows, and like thermostat I1, preferably makes or breaks electrical connection with a snap action.

As shown-in Fig'. 2,' one of the elements of thermostat 25, as, for example its ilxed contact 25a, is electrically connected to the Junction of conductors 21 and 25. 'I'he temperature-sensitive element, 25h, oi' thermostat 25 may be electure of element I8 appreciably more than 30 F.

The heating eilect of the two coils 23, 24-adds to the '10 outdoor temperature, elevating the temperature Vof element I5 to a point appreciably greater than 100 F.-in otherwords, a temperature more than sufficient to maintain the thermostat I1, and hence circuit 20, 2l, in open circuit status. Control means 22 being assumed to ,operate to close oil thermal medium ow through the heating system under such open cirsuit condition, thermal ilow to radiators I0, Ita,

Acan not occur at this outdoor temperature condition.

Should the outdoor temperature drop from '10 F., the sum of the heat outputl of coils 23, 24, and the outdoor temperature begins to approach the circuit closing temperature of thermostat element I5. At 64 F. outdoor temperature, at which temperature thermostat 25 closes contact, heating coil 23 is shunted out of the circuit,

and with the coil 24 being of calculated heat output insuiilcient alone to supplement the 64 F. outdoor temperature in maintaining the tem.- perature of thermostatic element I8 at a point above 100 F., the thermostat will close circuit 20, 2|, and through suitable action of control means 22', heat will be supplied to the heating system, inclusive vof control radiator I 0. As

steam begins to enter radiator I0 through valve I2b, negative resistance element vI3 will be warmed, and its resistance lowered. As the resistance of the major electrical control circuit is directly affected by a change in resistance of any trically connected, as by conductor 35, to a point intermediate heating elements 23, 24'.

The resistance value ofthe circuit of thermostat 25, including the leads eil'ecting its connection to the major circuit, should be considerably less than the resistance value o! heating element 23.' In the circumstance ofan open circuit at 25a, the path of current ilow will be through heating elements 23, 24; with circuit at 25a closed,

however, heating coil 23, because of its great resistance in comparison to that of the auxiliary thermostat system 25, will be electrically bypassed.

As typical of setting-point values for thermostats II and 25, it may be considered that thermostat I1 is setto open circuit--that is, blade I3 is set to move out of contact-with element I3-at a temperature just above 100 F; The thermostat 25 is set so that the movable blade 25h moves' to the right as viewed in'Fig. 2 and electrically engages xed contact 25a and closes the circuit when the outdoor temperature reaches and falls below 64 F., .and the blade 25h moves tothe left and outof engagement with 25a and opens the circuit when the outdoor temperature'reaches 66 F. i Assuming the heating system to bein operation and an outdoor temperature of 70 F., it isv gen- Witha "cold radiator Ill, i. e., a radiatorelement 24 emits increased heat.

one of its component elements, and as the potential at 25 is substantially constant, the current ow, i. e., amperage, is increased. 'I'he heating value a-t coil 2'4 being Watts=I2R.,

SuchA increased heat emission may beetective, additively to the existing outdoor temperature, to raise the temperature of blade I8 to'above its circuit opening temperature, in which event ilow of thermal iluld will cease.

Should the temperature continue to fall, and at a rate faster than' the rate of'temperature increase at the surface of radiator I0, the heating of a second negative resistance element, I3a, ad-

ditionally reduces the overallresistance of thecircuit to aiiord increased heat output of the coil with a continuing drop of outdoor temperature --beyond the capacity of heating coil 24, as established by the hot, and therefore minimum resistance, characteristic of elements I3, I3a, to

elevate the temperature o1 element I3 to its circuit-opening point, the thermal medium will continue to flow into the radiator, warming additional of the resistance elements, thus additionally reducing the overall resistance of the electric circuit and increasing the heat output of coil 24. In severe outdoor weather, the ow of thermal medium into the radiator may continue, until control radiator I0 and radiators I 0a reach, and are maintained at, substantially com pletely filled condition at the. predetermined.

minimum outdoor temperature at which the heating system is designed to heat the building' or enclosure to the desired temperature. Assuming this minimum outdoor temperature to be zero degrees F.' when completely lled radiators are desired, the resistance of 'the electrical circuit is suitably proportioned that when the control radiator II) is completely lled, the current ilow through heating coil 24 provides suf-I heating coils 23, 24 serves to raise the temperav iicient heat emission from coil 25 to heat thermostat element I8 to a temperature of approximate- 1y 100 F. The maximum surface temperature of a radiator is limited Aby factors well known in the art, and therefore, with a completely filled radiator I0, the circuit may be so adjusted as to maintain the temperature of thermostat element I8 at a point not more than 100 F. at zero degrees outdoor temperature.

Should the outdoor temperature rise, the increased outdoor temperature, adding its heating eil'ectto thel heat output of coil 24, raises the temperature of thermostat element I8 sufdcient- 1y to open the circuit 20, 2li, and actuate control 22 to stop flow of thermal medium to the heating system. As radiator Ill, and therefore elements I3, I3a, I3b, I3c, begin to cool, the increased resistance of the circuit reduces the wattage through coil 24, and reduces its heating effect. Under this circumstance, the element I8 may again close circuit, or, the outdoor temperature may have risen to a point at which further cooling of elements I3, I3a, I3b, I3c is required before the heat output of coil 24 is re duced to a point at which its heat. effect, plus the heat eiect of the outdoor weather, is insumcient to maintain element I8 in open-circuit condition. y

It is evident, therefore,-that the 'temperature of the control radiator I and of other radiators Ilia may be definitely varied from cold status at a 65 to 70 F. outdoor temperature to a completely filled condition at a predetermined mnimum outdoor temperature.

As the outdoor temperature rises to 66 F. or above, the circuit controlled by thermostat 25 will open, placing coil 23 in series with coil 24. The combined heat output of 23 and 24 will quickly elevate the temperature of thermostat element I8 within housing I1 to above the 100 F. point, and heat supply to radiator I0, and consequently to other heating units of the system, will immediately cease.

Thermostat 25, while obviously not essential to the operation of the control system, ilnds particular utility in the use of my improved temperature control system for residence'or other building temperature control, in which it may be uneconomlc or impossible to design a heating system which will function with precise accuracy. In such installations, it is desirable, from the point of view of the building operator, to have absolutely "cold radiators with '70 outdoor temperature; further, in the average installation, no advantage i's gained by supplying heat to the ra.- diators until the outdoor temperature falls below 65 F. Thermostat 25 therefore acts as a limiting device for establishing an outdoor temperature point above which heat iiow to the radiators Ill, Illa is positively prevented.

Under certain conditions, as, for example. a commercial installation where the heat output of heat exchange units of the system may be Aestablished with a high degree of accuracy and other elements of the system held within close limits of design and installation, the heat output of a single coil, as 24, Fig. 5,- may be suitably proportioned and established in relationship to element I8 of thermostat I1 and it alone provides the accuracy and positive type of control desired. In such an installation, the auxiliary thermostat 25 may be employed in the manner Indicated in Fig. 5, Le., as a thermally responsive switch connected in'series in the circuit 20, 2|, and set to open the circuit at a predetermined outdoor assays? temperature, as` 66 F. As shown, the blade 25h moves to the right and out of contact with the stationary contact 25a upon an. increase in outdoor temperature beyond the predetermined temperature, 66 F. The series connection arrangement of thermostat 25 illustrated in Fig. 5 is merely typical; other known connections, involving two wire or three wire circuits, may be employed, depending upon the type of thermostat 25 or control 22 selected.

I have discovered that by suitably positioning the elements I3, I3a, i312, I 3c along the path of ow of heat medium through radiator I0, a substantially straight line relationship between average radiator temperature, as represented by the average temperature ofthe elements I3, I3a, i321, I3c, and outdoor temperature, may be obtained. Such straight line relationship is indicated in Fig. 3, in which lines 40, 4I, 42 are derived by plotting illustrative control element temperatures against outdoor temperatures, and represent three settings of rheostat 33, as presently described, A concentration of one-quarter or one-third of the total resistance of the stated elements at the rst one-Seventh o the radiator In is effective to produce a desired straight line relation.

Referring to Fig, 3, it may be considered that line -4I represents a radiator installation which is theoretically accurate, i. e., an installation in which the radiators, when completely lled, maintain the desired indoor temperature under conditions of predetermined minimum outdoor temperature. cold radiator at an outdoor temperature approximately 65 to 70 F., and a completely filled radiator at zero degrees outdoor temperature. As above stated, the absclssa temperatures represent, not the surface temperature of the control radiator I0, but the average temperature of the control elements I3, I3a, I3b, |30, which when positioned on the radiator surface in a manner electrically insulated therefrom, Will obviously not reach the temperature of such radiator surface.

In practice, the condition is often met where the radiator Installation is insuilicient to produce a desired indoor temperature for the predetermined minimum outdoor temperature, such minimum outdoor temperatures being experienced only occasionally during the normal heating season. It is therefore desirable, and may be essential, to provide means whereby the radiator I0, and hence the other radiators I 0a of the heating system, may be maintained at a warmer temperature condition during the mild or average outdoor weather condition, to offset such deciency in actual radiation. A straight line temperature relationship between outdoor and control elements temperatures for such condition is illustrated by line 42, in which, by reference to the horizontal line established at approximately 55 F. it is indicated that a warmer radiator temperature condition is achieved than under a circumstance of theoretically accurate radiation. Similarly, line 40 may indicate a condition of excess radiation, for which circumstance a lower temperature of the control elements provides the wattage and resultant heat 'output of the heating elements in heat-radiating relationship to the thermostat blade I8 of thermostat I1, necessary to maintain the contact of I8 and I9 at the desired operating status for kthe 4predetermined minimum outdoor temperature.

Line 4I, therefore, indicates a It isa feature of the present invention that means are provided whereby the straight line temperature relationship may be altered, as indicated in Fig. 3, to accommodate for such varying conditions and eiciencies of heating installations.

perature4 regulation in the space isI de-I sired and said circuit connecting said electrical I heating means and said electricalresistance ele- As an example of such control means, I proment so that during suchperiod heat is continuously supplied to said enclosure and the amount of heat supplied thereto varies in pro' o portion to the temperature of said thermal element; and thermostatic means responsive to the enclosure temperature asaffected by the kamount within a comparatively limited range, the slope of the line is appreciably altered Increasing the resistance at 33 automatically decreases the wattage output of the heating elements Within the housing l1, and has the effect of raising the ordinate point from that represented by the line 4I, for example, to that represented by the line 4,2 of Fig. 3. This results from the altered temperature condition within the housing l1', as

-when the heat output of the heating element decreases, the attainment of the set operating temperature for thermostat I1 must result from an increase in outdoor temperature. Also, the increase of resistance33 so alters the entire resistance of the circuit that a change in resistance 4of one element thereof, such as a change in resistance of one or more of the elements I3, I3a, I3b, I3c has proportionally less effect. An increase of such resistance of 33 materially alters the slope of the straight line relationship between outdoor temperature and radiator temperature.

Thus, While it is possible to maintain the intersection of the plottedternperature relationship line with the ordinate within a comparatively close range, the relationship of zero degrees outdoor temperature to average control radiator' temperature may b e appreciably changed, and a desired relationship of radiator temperature to outdoor temperature maybe definitely established.

The adjustment of rheostat 33 may be controlled by a suitable timing device, in conformity with residential practice of maintaining a less temperature at night than during normal Waking hours.

While I have illustrated my invention by a representation and description of a typical arrangement thereof, it will be understood that many changes may be made inthe arrangementl of component elements and in the electrical circuit within the spirit of the linvention and the scope of the appended claims.

I claim:

1. lApparatus for controlling thel temperature of a building space comprising a thermal element in heat-transfer relation with respect to said space and adapted to be supplied with a thermal medium; an enclosure located outside of said building space and in heat-dissipating Arelation with the outdoor atmosphere so that the rate of heat dissipation 'therefrom is determined partly by the outdoor temperature; electrical heating.

means for supplying heat to said enclosure; an electrical resistance element subjected ,directly to the temperature of said thermal element and b eingso constructed that the value of its resistance varies in proportion to its temperature; an electrical circuit including means for constantly energizing the same during the period when the outdoor temperature is below a value where temof heat supplied by said electrical heating means and the rate at which heat is dissipated to the outdoor atmosphere, and operable to regulate the amount of thermal medium supplied -to said thermal element in accordance with said en` closure temperature.

2. Apparatus for controlling the temperatur of a building space comprising a thermal element -in heat-transfer relation with respect tosaid space and adapted to be supplied with a thermal medium; an enclosure located outside of said building space and in heat `dissipating relation with the outdoor atmosphere so that the rate Aof heat dissipation therefrom `is determined partly by' the outdoor temperature; /electrical heating means for supplying heat to said enclosure; an electrical resistance element sub-- jected directly to the temperature of said thermal Velement and being so constructed that its resistance value varies in proportion to its temperattire; an electrical circuit including means for constantly energizing the same during the period when the outdoor temperature is below a value where temperature regulation in the building space is desired and said circuit connecting saidelectrical heating means and said electric-al resistance element so that during such period heat is continuously supplied to said enclosure and the amount of heat supplied thereto varies in proportion to the temperature of said thermal element; thermost-atic means responsive to the enclosure temperature as affected by the amount-of heat supplied by said electrical heating means 1 and the rateiat which heat is dissipated to the outdoor atmosphere, and operable to regulate the amount of thermal medium supplied to said thermal element in accordance with said enclosure temperature; and a second thermostatic means responsive to outdoor temperature and operable to prevent the supply of thermal medium to said thermal elementy when the outdoor temperature attains a predetermined value where temperature regulation within said space is not desired.

3. Apparatus for controlling the temperature of a building space comprising a thermal element in heat-transfer relation with respect to said space and adapted to be supplied with a thermal medium; an enclosure located outside of said building space and in heat-dissipating relation with the outdoor atmosphere so that the rate of heat dissipation therefrom is determined partly by the outdoor temperature; electrical heating means for supplyingheat to said enclosure; an electrical resistance element subjected directly to the temperature of said thermal element and being so constructed' that its' resistance value varies in proportion to its temperature; lan electrical circuit including means for constantly energizing the same during the vperiod when the outdoor ltemperature is below a value where temperature regulation in the building space is desired and said circuit connecting said electrical heating means and said electrical resistance element so thatduring such period heat is continuously supplied to said enclosure and the when the outdoor temperature attains a predetermined value where temperature regulation within said space, is not desired.

4. Apparatus for controlling the temperature of a building space comprising a thermal element in heat-transfer relation with respect to said space and adapted to be supplied with a thermal medium; an enclosure located outside of said building space and in heat-dissipating relation with the outdoor atmosphere so that therate of heat dissipation therefrom is determined partly y by the outdoor temperature; electrical heating means for supplying heat to said. enclosure; an electrical resistance element subjected directly to the temperature of said thermal element and being so constructed that its resistance value varies in proportion to its temperature; a constantly energized electrical circuit connecting said electrical heating means and said electrical resistance element so that heat is continuously supplied to said enclosure and the amount of heat supplied thereto varies in proportion to the temperature of said thermal element; thermostatic means responsive to the enclosure temperature as affected by the amount of lheat supplied by said electrical heating means and the rate at-which heat is dissipated to the outdoor atmosphere, and operable to regulate the amount of thermal medium supplied to said thermal element in accordance with said enclosure temperature; and a second thermostatic means operable to' render said first thermostatic means ineffective to control the supply of thermal medium when the outdoor temperature attains a predetermined value where temperature regulation in said space is not desired.

5. Apparatus for maintaining the temperature of a building space within a relatively narrow range and comprising a thermal element in heat-transfer relation with respect to said space and adapted to be supplied with a thermal medium; an enclosure located outside of said build-- ing space and in heat-dissipating relation with the outdoor atmosphere so that the .rate of heat supplied to said enclosure and by the rate at which heat is dissipated to the outdoor atmosphere, and operable to regulate the amount of thermal medium supplied to said thermal element in accordance with said enclosure 'temperature; a second electrical heating element arranged to supply heat to said enclosure; and a second thermostatic means responsive to outdoor temperature and operable to connect said second electrical heating element into said electrical circuit when outdoor temperature reaches a predetermined point where temperature regulation insaid space is not desired. y

6. Apparatus for maintaining the temperature of a building space within a relatively narrow range during the heating season and comprising a heat-emitting element disposed to transmit heat to said space and adapted to be supplied with a heating`medium; an enclosure located outside of said building space and in position to dissipate heat to the outdoor atmosphere; electrical heating means arranged to add heat to said enclosure so that the enclosure temperature is above the outdoor' temperature and so that heat is dissipated from the enclosure to the outdoor atmosphere at a rate which is determined by the amount of heat energy supplied by said electrical heating means and byI the outdoor temperature; an electrical resistance element directly subjected to the temperature of said .heatemitting element and being so constructed that 'its resistance value varies in proportion to its including temperature; an electrical circuit means for constantly energizing the same during the period when the outdoor temperature is be-l low a value where temperatureregulation in the building space is desired and said circuit connecting said electrical heating means and said electrical resistance element so that during such period heat is continuously supplied to said enclosure .and the amount of heat supplied varies inproportion to the temperature of said heatdissipation therefrom'is determined' partly by the outdoor temperature; a first electrical heating element arranged to supply heat to said enclosure; an electrical .resistance element subjected directly to the temperature of said thermal element and being so constructed that the value of its resistance varies in proportion to its temperature; Van electrical circuit including means for constantly energizing the same during the period when the outdoor temperature is below a value where temperature regulation in thev building space is desired and said circuit connecting said rst electrical' heating element and said electrical resistance element so that during such period heat is continuously supplied to said -enclosure in amounts varying in proportion to the temperature of. said thermal element;

thermostatic means responsive to enclosure temv perature as determined by the amount of heat -emitting element; and thermostatic means responsive to the temperature of said enclosure and operable to vary the supply of heating medium to said heat-emitting element in direct proportion to the rate of heatdissipation from said enclosure.

7. Apparatus for maintaining the temperature of a building space withina relatively narrow range during the heating season and comprising a heat-emitting element disposed to transmit heat to said space and adapted to be supplied with a heating medium; an enclosure located outside of said building space'and in position to dissipate heat to the outdoor atmosphere; electrical heating means arranged to add heat to said enclosure so that the enclosure temperature is'above the outdoor temperature and so that -heat is dissipated from 'the enclosure to the outdoor atmosphere at a rate which is determined by the amount of heat energy supplied by said electrical heating means and by the outdoor temperairre; an' electrical resistance element dI- rectly' subjected to the temperature oi' said heatemitting element and being so constructed that its resistance value varies in inverse proportion to its temperature: an electrical circuit including means fof constantly energizing the same during the period whenthe outdoor temperature 1 is below a. value where temperature regulation in the building space is desired and said circuit connecting said electrical heating means and .said electrical resistance element so that during suon period heet is eontinuousiy supplied to seid enclosure and the amount of heat supplied varies in direct proportion to the temperature of said heat-emitting element; and thermostatic means responsive to the temperature of said enclosure and operable to vary the supply of heating medium to said heat-emitting element in direct proportion to the rate of heat dissipation from said enclosure.

8. Apparatus for maintaining the temperature 1'0 of a building space within a relatively narrow range during the heating season and comprising 'a hollow heat-exchange element disposed to Y transmit heat to said space and adapted tobe supplied with -a heating uid; an enclosure lo- 15 is above the outdoor temperature and' so that 20 heat is dissipated from the enclosure at a rate which is determined by the amount of heat supplied to the enclosure and by the outdoor temperature; a plurality of electrical resistance elements so constructed that their resistance values vary respectively in proportion to their temperatures and said resistance elements being conriected in electrical series and distributed over said heat-exchange element in such a manner lthat their total electrical resistance varies in pro 30 portion to the average temperature of said heatexchange element; an electrical circuit including means for constantly energizing the same during the period when the outdoor temperature is below a velue where temperature regulation in the building space is desired and said circuit connecting said resistance elements and said electrical heating means so that during such period heat is continuously supplied to said enclosure and in amounts varying in proportion to the d0 average temperature of said heat-exchange element; and thermostatic means responsive to the temperature o said enclosure and operable to vary the supply ,of heating uid to said heatof heat dissipation from said enclosure.

9. Apparatus for maintaing the temperature of. a building space within a relatively nanrow range during the heating season and comprising a heatemitting element disposed to transmit heat to said space and adapted to be lsupplied with a heating medium; an enclosure located outside of said space and in position to dissipate heat to the outdoor atmosphere so that the rate of heat dissipated therefrom is determined partly by the outdoor temperature; electrical heating-means arranged to add heat to said enclosure to raise the temperature oi the latter to a predetermined control point which is above the outdoor temits' resistance value varies in proportion t0 its temperature; an electrical circuit including means for constantly energizing the same during the' period when the outdoor temperature is below a value where temperature regulationin the building space is desired and said circuit connecting said electrical heating means and vsaid electrical resistance element so that during such period heat is continuously supplied t0 said en`- closure and in amounts varying inproportion to the temperature of said heat-emitting element;

" and thermostatic means responsive to the temperature of said enclosure as determined by the amount of heat supplied by said electrical heating means and by the rate of heat dissipation to the outdoor atmosphere. and operable to effect the supply of heating-medium to said heat-emitting element when the temperature of said enclosure is below said predetermined control point and to prevent the supply of heating medium to said heat-emitting element when the temperature of said enclosure is above said control point.

10. Apparatus for maintaining the temperature of a building space within a relatively narrow range during the heating season and comprising a heat-emitting element disposed to transmit heat to' said space and adapted to bewsupplied with a heating medium; an enclosure located outside of said space and in position to dissipate heat to the outdoor atmosphere so that the rate of heet dissipated therefrom is determined pertly by the outdoor temperature; electrical heating means arranged to add heat to said enclosure to raise the temperature of the latter to avpredetermined control point which is above the outdoor temperature; an electrical resistance element directly subjected to the temperature of said heatemitting element and being; so constructed that its resistance value varies in lproportion to its temperature; an electrical circuit including means for constantly energizing the same during the period when the outdoor temperature is below a value where temperature regulation in the building space is desired and said circuit conexchange element in direct proportion to the rate 45 necting said electrical heating means and said electrical resistance element so thatduring such period heat is continuously supplied to said enclosure and in amounts varying in proportion to.

the temperature of said heat-emitting element; an electrically operated device operable when energized to supply a heating medium to said heat-emitting element; a second electrical circuit for energizing said device; a switch for opening and closing said second circuit; and thermostatic .means movable inresp'onse to enclosure perature; an electrical resistance element' di- 60 said control point. o'

rectly subjected to the temperature of saldheatemitting element and being so constructed that 

